da0af40dd7
When trying to load an ELF file specified via -kernel, we need to pass load_elf() the ELF machine type corresponding to the CPU we're booting with, not the one corresponding to the softmmu binary we happen to be running. (The two are different in the case of loading a 32-bit ARM ELF file into a 32 bit CPU being emulated by qemu-system aarch64.) This was causing us to incorrectly fail to load ELF images in this situation. Signed-off-by: Peter Maydell <peter.maydell@linaro.org> Reviewed-by: Andreas Färber <afaerber@suse.de> Message-id: 1395427476-25546-1-git-send-email-peter.maydell@linaro.org
591 lines
18 KiB
C
591 lines
18 KiB
C
/*
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* ARM kernel loader.
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*
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* Copyright (c) 2006-2007 CodeSourcery.
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* Written by Paul Brook
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*
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* This code is licensed under the GPL.
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*/
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#include "config.h"
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#include "hw/hw.h"
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#include "hw/arm/arm.h"
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#include "sysemu/sysemu.h"
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#include "hw/boards.h"
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#include "hw/loader.h"
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#include "elf.h"
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#include "sysemu/device_tree.h"
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#include "qemu/config-file.h"
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#include "exec/address-spaces.h"
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/* Kernel boot protocol is specified in the kernel docs
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* Documentation/arm/Booting and Documentation/arm64/booting.txt
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* They have different preferred image load offsets from system RAM base.
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*/
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#define KERNEL_ARGS_ADDR 0x100
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#define KERNEL_LOAD_ADDR 0x00010000
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#define KERNEL64_LOAD_ADDR 0x00080000
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typedef enum {
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FIXUP_NONE = 0, /* do nothing */
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FIXUP_TERMINATOR, /* end of insns */
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FIXUP_BOARDID, /* overwrite with board ID number */
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FIXUP_ARGPTR, /* overwrite with pointer to kernel args */
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FIXUP_ENTRYPOINT, /* overwrite with kernel entry point */
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FIXUP_GIC_CPU_IF, /* overwrite with GIC CPU interface address */
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FIXUP_BOOTREG, /* overwrite with boot register address */
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FIXUP_DSB, /* overwrite with correct DSB insn for cpu */
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FIXUP_MAX,
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} FixupType;
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typedef struct ARMInsnFixup {
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uint32_t insn;
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FixupType fixup;
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} ARMInsnFixup;
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static const ARMInsnFixup bootloader_aarch64[] = {
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{ 0x580000c0 }, /* ldr x0, arg ; Load the lower 32-bits of DTB */
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{ 0xaa1f03e1 }, /* mov x1, xzr */
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{ 0xaa1f03e2 }, /* mov x2, xzr */
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{ 0xaa1f03e3 }, /* mov x3, xzr */
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{ 0x58000084 }, /* ldr x4, entry ; Load the lower 32-bits of kernel entry */
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{ 0xd61f0080 }, /* br x4 ; Jump to the kernel entry point */
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{ 0, FIXUP_ARGPTR }, /* arg: .word @DTB Lower 32-bits */
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{ 0 }, /* .word @DTB Higher 32-bits */
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{ 0, FIXUP_ENTRYPOINT }, /* entry: .word @Kernel Entry Lower 32-bits */
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{ 0 }, /* .word @Kernel Entry Higher 32-bits */
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{ 0, FIXUP_TERMINATOR }
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};
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/* The worlds second smallest bootloader. Set r0-r2, then jump to kernel. */
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static const ARMInsnFixup bootloader[] = {
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{ 0xe3a00000 }, /* mov r0, #0 */
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{ 0xe59f1004 }, /* ldr r1, [pc, #4] */
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{ 0xe59f2004 }, /* ldr r2, [pc, #4] */
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{ 0xe59ff004 }, /* ldr pc, [pc, #4] */
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{ 0, FIXUP_BOARDID },
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{ 0, FIXUP_ARGPTR },
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{ 0, FIXUP_ENTRYPOINT },
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{ 0, FIXUP_TERMINATOR }
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};
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/* Handling for secondary CPU boot in a multicore system.
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* Unlike the uniprocessor/primary CPU boot, this is platform
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* dependent. The default code here is based on the secondary
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* CPU boot protocol used on realview/vexpress boards, with
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* some parameterisation to increase its flexibility.
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* QEMU platform models for which this code is not appropriate
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* should override write_secondary_boot and secondary_cpu_reset_hook
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* instead.
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*
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* This code enables the interrupt controllers for the secondary
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* CPUs and then puts all the secondary CPUs into a loop waiting
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* for an interprocessor interrupt and polling a configurable
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* location for the kernel secondary CPU entry point.
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*/
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#define DSB_INSN 0xf57ff04f
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#define CP15_DSB_INSN 0xee070f9a /* mcr cp15, 0, r0, c7, c10, 4 */
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static const ARMInsnFixup smpboot[] = {
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{ 0xe59f2028 }, /* ldr r2, gic_cpu_if */
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{ 0xe59f0028 }, /* ldr r0, bootreg_addr */
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{ 0xe3a01001 }, /* mov r1, #1 */
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{ 0xe5821000 }, /* str r1, [r2] - set GICC_CTLR.Enable */
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{ 0xe3a010ff }, /* mov r1, #0xff */
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{ 0xe5821004 }, /* str r1, [r2, 4] - set GIC_PMR.Priority to 0xff */
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{ 0, FIXUP_DSB }, /* dsb */
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{ 0xe320f003 }, /* wfi */
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{ 0xe5901000 }, /* ldr r1, [r0] */
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{ 0xe1110001 }, /* tst r1, r1 */
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{ 0x0afffffb }, /* beq <wfi> */
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{ 0xe12fff11 }, /* bx r1 */
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{ 0, FIXUP_GIC_CPU_IF }, /* gic_cpu_if: .word 0x.... */
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{ 0, FIXUP_BOOTREG }, /* bootreg_addr: .word 0x.... */
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{ 0, FIXUP_TERMINATOR }
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};
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static void write_bootloader(const char *name, hwaddr addr,
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const ARMInsnFixup *insns, uint32_t *fixupcontext)
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{
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/* Fix up the specified bootloader fragment and write it into
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* guest memory using rom_add_blob_fixed(). fixupcontext is
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* an array giving the values to write in for the fixup types
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* which write a value into the code array.
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*/
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int i, len;
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uint32_t *code;
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len = 0;
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while (insns[len].fixup != FIXUP_TERMINATOR) {
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len++;
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}
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code = g_new0(uint32_t, len);
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for (i = 0; i < len; i++) {
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uint32_t insn = insns[i].insn;
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FixupType fixup = insns[i].fixup;
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switch (fixup) {
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case FIXUP_NONE:
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break;
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case FIXUP_BOARDID:
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case FIXUP_ARGPTR:
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case FIXUP_ENTRYPOINT:
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case FIXUP_GIC_CPU_IF:
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case FIXUP_BOOTREG:
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case FIXUP_DSB:
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insn = fixupcontext[fixup];
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break;
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default:
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abort();
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}
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code[i] = tswap32(insn);
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}
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rom_add_blob_fixed(name, code, len * sizeof(uint32_t), addr);
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g_free(code);
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}
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static void default_write_secondary(ARMCPU *cpu,
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const struct arm_boot_info *info)
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{
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uint32_t fixupcontext[FIXUP_MAX];
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fixupcontext[FIXUP_GIC_CPU_IF] = info->gic_cpu_if_addr;
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fixupcontext[FIXUP_BOOTREG] = info->smp_bootreg_addr;
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if (arm_feature(&cpu->env, ARM_FEATURE_V7)) {
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fixupcontext[FIXUP_DSB] = DSB_INSN;
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} else {
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fixupcontext[FIXUP_DSB] = CP15_DSB_INSN;
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}
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write_bootloader("smpboot", info->smp_loader_start,
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smpboot, fixupcontext);
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}
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static void default_reset_secondary(ARMCPU *cpu,
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const struct arm_boot_info *info)
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{
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CPUARMState *env = &cpu->env;
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stl_phys_notdirty(&address_space_memory, info->smp_bootreg_addr, 0);
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env->regs[15] = info->smp_loader_start;
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}
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static inline bool have_dtb(const struct arm_boot_info *info)
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{
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return info->dtb_filename || info->get_dtb;
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}
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#define WRITE_WORD(p, value) do { \
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stl_phys_notdirty(&address_space_memory, p, value); \
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p += 4; \
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} while (0)
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static void set_kernel_args(const struct arm_boot_info *info)
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{
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int initrd_size = info->initrd_size;
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hwaddr base = info->loader_start;
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hwaddr p;
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p = base + KERNEL_ARGS_ADDR;
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/* ATAG_CORE */
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WRITE_WORD(p, 5);
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WRITE_WORD(p, 0x54410001);
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WRITE_WORD(p, 1);
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WRITE_WORD(p, 0x1000);
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WRITE_WORD(p, 0);
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/* ATAG_MEM */
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/* TODO: handle multiple chips on one ATAG list */
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WRITE_WORD(p, 4);
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WRITE_WORD(p, 0x54410002);
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WRITE_WORD(p, info->ram_size);
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WRITE_WORD(p, info->loader_start);
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if (initrd_size) {
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/* ATAG_INITRD2 */
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WRITE_WORD(p, 4);
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WRITE_WORD(p, 0x54420005);
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WRITE_WORD(p, info->initrd_start);
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WRITE_WORD(p, initrd_size);
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}
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if (info->kernel_cmdline && *info->kernel_cmdline) {
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/* ATAG_CMDLINE */
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int cmdline_size;
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cmdline_size = strlen(info->kernel_cmdline);
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cpu_physical_memory_write(p + 8, info->kernel_cmdline,
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cmdline_size + 1);
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cmdline_size = (cmdline_size >> 2) + 1;
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WRITE_WORD(p, cmdline_size + 2);
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WRITE_WORD(p, 0x54410009);
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p += cmdline_size * 4;
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}
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if (info->atag_board) {
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/* ATAG_BOARD */
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int atag_board_len;
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uint8_t atag_board_buf[0x1000];
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atag_board_len = (info->atag_board(info, atag_board_buf) + 3) & ~3;
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WRITE_WORD(p, (atag_board_len + 8) >> 2);
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WRITE_WORD(p, 0x414f4d50);
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cpu_physical_memory_write(p, atag_board_buf, atag_board_len);
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p += atag_board_len;
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}
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/* ATAG_END */
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WRITE_WORD(p, 0);
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WRITE_WORD(p, 0);
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}
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static void set_kernel_args_old(const struct arm_boot_info *info)
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{
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hwaddr p;
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const char *s;
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int initrd_size = info->initrd_size;
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hwaddr base = info->loader_start;
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/* see linux/include/asm-arm/setup.h */
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p = base + KERNEL_ARGS_ADDR;
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/* page_size */
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WRITE_WORD(p, 4096);
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/* nr_pages */
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WRITE_WORD(p, info->ram_size / 4096);
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/* ramdisk_size */
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WRITE_WORD(p, 0);
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#define FLAG_READONLY 1
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#define FLAG_RDLOAD 4
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#define FLAG_RDPROMPT 8
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/* flags */
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WRITE_WORD(p, FLAG_READONLY | FLAG_RDLOAD | FLAG_RDPROMPT);
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/* rootdev */
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WRITE_WORD(p, (31 << 8) | 0); /* /dev/mtdblock0 */
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/* video_num_cols */
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WRITE_WORD(p, 0);
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/* video_num_rows */
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WRITE_WORD(p, 0);
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/* video_x */
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WRITE_WORD(p, 0);
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/* video_y */
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WRITE_WORD(p, 0);
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/* memc_control_reg */
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WRITE_WORD(p, 0);
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/* unsigned char sounddefault */
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/* unsigned char adfsdrives */
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/* unsigned char bytes_per_char_h */
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/* unsigned char bytes_per_char_v */
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WRITE_WORD(p, 0);
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/* pages_in_bank[4] */
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WRITE_WORD(p, 0);
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WRITE_WORD(p, 0);
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WRITE_WORD(p, 0);
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WRITE_WORD(p, 0);
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/* pages_in_vram */
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WRITE_WORD(p, 0);
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/* initrd_start */
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if (initrd_size) {
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WRITE_WORD(p, info->initrd_start);
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} else {
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WRITE_WORD(p, 0);
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}
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/* initrd_size */
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WRITE_WORD(p, initrd_size);
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/* rd_start */
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WRITE_WORD(p, 0);
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/* system_rev */
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WRITE_WORD(p, 0);
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/* system_serial_low */
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WRITE_WORD(p, 0);
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/* system_serial_high */
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WRITE_WORD(p, 0);
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/* mem_fclk_21285 */
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WRITE_WORD(p, 0);
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/* zero unused fields */
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while (p < base + KERNEL_ARGS_ADDR + 256 + 1024) {
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WRITE_WORD(p, 0);
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}
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s = info->kernel_cmdline;
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if (s) {
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cpu_physical_memory_write(p, s, strlen(s) + 1);
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} else {
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WRITE_WORD(p, 0);
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}
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}
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static int load_dtb(hwaddr addr, const struct arm_boot_info *binfo)
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{
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void *fdt = NULL;
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int size, rc;
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uint32_t acells, scells;
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if (binfo->dtb_filename) {
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char *filename;
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filename = qemu_find_file(QEMU_FILE_TYPE_BIOS, binfo->dtb_filename);
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if (!filename) {
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fprintf(stderr, "Couldn't open dtb file %s\n", binfo->dtb_filename);
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goto fail;
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}
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fdt = load_device_tree(filename, &size);
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if (!fdt) {
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fprintf(stderr, "Couldn't open dtb file %s\n", filename);
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g_free(filename);
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goto fail;
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}
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g_free(filename);
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} else if (binfo->get_dtb) {
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fdt = binfo->get_dtb(binfo, &size);
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if (!fdt) {
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fprintf(stderr, "Board was unable to create a dtb blob\n");
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goto fail;
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}
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}
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acells = qemu_fdt_getprop_cell(fdt, "/", "#address-cells");
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scells = qemu_fdt_getprop_cell(fdt, "/", "#size-cells");
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if (acells == 0 || scells == 0) {
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fprintf(stderr, "dtb file invalid (#address-cells or #size-cells 0)\n");
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goto fail;
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}
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if (scells < 2 && binfo->ram_size >= (1ULL << 32)) {
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/* This is user error so deserves a friendlier error message
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* than the failure of setprop_sized_cells would provide
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*/
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fprintf(stderr, "qemu: dtb file not compatible with "
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"RAM size > 4GB\n");
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goto fail;
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}
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rc = qemu_fdt_setprop_sized_cells(fdt, "/memory", "reg",
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acells, binfo->loader_start,
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scells, binfo->ram_size);
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if (rc < 0) {
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fprintf(stderr, "couldn't set /memory/reg\n");
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goto fail;
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}
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if (binfo->kernel_cmdline && *binfo->kernel_cmdline) {
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rc = qemu_fdt_setprop_string(fdt, "/chosen", "bootargs",
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binfo->kernel_cmdline);
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if (rc < 0) {
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fprintf(stderr, "couldn't set /chosen/bootargs\n");
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goto fail;
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}
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}
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if (binfo->initrd_size) {
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rc = qemu_fdt_setprop_cell(fdt, "/chosen", "linux,initrd-start",
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binfo->initrd_start);
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if (rc < 0) {
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fprintf(stderr, "couldn't set /chosen/linux,initrd-start\n");
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goto fail;
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}
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rc = qemu_fdt_setprop_cell(fdt, "/chosen", "linux,initrd-end",
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binfo->initrd_start + binfo->initrd_size);
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if (rc < 0) {
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fprintf(stderr, "couldn't set /chosen/linux,initrd-end\n");
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goto fail;
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}
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}
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if (binfo->modify_dtb) {
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binfo->modify_dtb(binfo, fdt);
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}
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qemu_fdt_dumpdtb(fdt, size);
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cpu_physical_memory_write(addr, fdt, size);
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g_free(fdt);
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return 0;
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fail:
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g_free(fdt);
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return -1;
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}
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static void do_cpu_reset(void *opaque)
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{
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ARMCPU *cpu = opaque;
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CPUARMState *env = &cpu->env;
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const struct arm_boot_info *info = env->boot_info;
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cpu_reset(CPU(cpu));
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if (info) {
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if (!info->is_linux) {
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/* Jump to the entry point. */
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env->regs[15] = info->entry & 0xfffffffe;
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env->thumb = info->entry & 1;
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} else {
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if (CPU(cpu) == first_cpu) {
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if (env->aarch64) {
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env->pc = info->loader_start;
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} else {
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env->regs[15] = info->loader_start;
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}
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if (!have_dtb(info)) {
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if (old_param) {
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set_kernel_args_old(info);
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} else {
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set_kernel_args(info);
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}
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}
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} else {
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info->secondary_cpu_reset_hook(cpu, info);
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}
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}
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}
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}
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void arm_load_kernel(ARMCPU *cpu, struct arm_boot_info *info)
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{
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CPUState *cs = CPU(cpu);
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int kernel_size;
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int initrd_size;
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int is_linux = 0;
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uint64_t elf_entry;
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int elf_machine;
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hwaddr entry, kernel_load_offset;
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int big_endian;
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static const ARMInsnFixup *primary_loader;
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/* Load the kernel. */
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if (!info->kernel_filename) {
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/* If no kernel specified, do nothing; we will start from address 0
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* (typically a boot ROM image) in the same way as hardware.
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*/
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return;
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}
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if (arm_feature(&cpu->env, ARM_FEATURE_AARCH64)) {
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primary_loader = bootloader_aarch64;
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kernel_load_offset = KERNEL64_LOAD_ADDR;
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elf_machine = EM_AARCH64;
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} else {
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primary_loader = bootloader;
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kernel_load_offset = KERNEL_LOAD_ADDR;
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elf_machine = EM_ARM;
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}
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info->dtb_filename = qemu_opt_get(qemu_get_machine_opts(), "dtb");
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if (!info->secondary_cpu_reset_hook) {
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info->secondary_cpu_reset_hook = default_reset_secondary;
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|
}
|
|
if (!info->write_secondary_boot) {
|
|
info->write_secondary_boot = default_write_secondary;
|
|
}
|
|
|
|
if (info->nb_cpus == 0)
|
|
info->nb_cpus = 1;
|
|
|
|
#ifdef TARGET_WORDS_BIGENDIAN
|
|
big_endian = 1;
|
|
#else
|
|
big_endian = 0;
|
|
#endif
|
|
|
|
/* We want to put the initrd far enough into RAM that when the
|
|
* kernel is uncompressed it will not clobber the initrd. However
|
|
* on boards without much RAM we must ensure that we still leave
|
|
* enough room for a decent sized initrd, and on boards with large
|
|
* amounts of RAM we must avoid the initrd being so far up in RAM
|
|
* that it is outside lowmem and inaccessible to the kernel.
|
|
* So for boards with less than 256MB of RAM we put the initrd
|
|
* halfway into RAM, and for boards with 256MB of RAM or more we put
|
|
* the initrd at 128MB.
|
|
*/
|
|
info->initrd_start = info->loader_start +
|
|
MIN(info->ram_size / 2, 128 * 1024 * 1024);
|
|
|
|
/* Assume that raw images are linux kernels, and ELF images are not. */
|
|
kernel_size = load_elf(info->kernel_filename, NULL, NULL, &elf_entry,
|
|
NULL, NULL, big_endian, elf_machine, 1);
|
|
entry = elf_entry;
|
|
if (kernel_size < 0) {
|
|
kernel_size = load_uimage(info->kernel_filename, &entry, NULL,
|
|
&is_linux);
|
|
}
|
|
if (kernel_size < 0) {
|
|
entry = info->loader_start + kernel_load_offset;
|
|
kernel_size = load_image_targphys(info->kernel_filename, entry,
|
|
info->ram_size - kernel_load_offset);
|
|
is_linux = 1;
|
|
}
|
|
if (kernel_size < 0) {
|
|
fprintf(stderr, "qemu: could not load kernel '%s'\n",
|
|
info->kernel_filename);
|
|
exit(1);
|
|
}
|
|
info->entry = entry;
|
|
if (is_linux) {
|
|
uint32_t fixupcontext[FIXUP_MAX];
|
|
|
|
if (info->initrd_filename) {
|
|
initrd_size = load_ramdisk(info->initrd_filename,
|
|
info->initrd_start,
|
|
info->ram_size -
|
|
info->initrd_start);
|
|
if (initrd_size < 0) {
|
|
initrd_size = load_image_targphys(info->initrd_filename,
|
|
info->initrd_start,
|
|
info->ram_size -
|
|
info->initrd_start);
|
|
}
|
|
if (initrd_size < 0) {
|
|
fprintf(stderr, "qemu: could not load initrd '%s'\n",
|
|
info->initrd_filename);
|
|
exit(1);
|
|
}
|
|
} else {
|
|
initrd_size = 0;
|
|
}
|
|
info->initrd_size = initrd_size;
|
|
|
|
fixupcontext[FIXUP_BOARDID] = info->board_id;
|
|
|
|
/* for device tree boot, we pass the DTB directly in r2. Otherwise
|
|
* we point to the kernel args.
|
|
*/
|
|
if (have_dtb(info)) {
|
|
/* Place the DTB after the initrd in memory. Note that some
|
|
* kernels will trash anything in the 4K page the initrd
|
|
* ends in, so make sure the DTB isn't caught up in that.
|
|
*/
|
|
hwaddr dtb_start = QEMU_ALIGN_UP(info->initrd_start + initrd_size,
|
|
4096);
|
|
if (load_dtb(dtb_start, info)) {
|
|
exit(1);
|
|
}
|
|
fixupcontext[FIXUP_ARGPTR] = dtb_start;
|
|
} else {
|
|
fixupcontext[FIXUP_ARGPTR] = info->loader_start + KERNEL_ARGS_ADDR;
|
|
if (info->ram_size >= (1ULL << 32)) {
|
|
fprintf(stderr, "qemu: RAM size must be less than 4GB to boot"
|
|
" Linux kernel using ATAGS (try passing a device tree"
|
|
" using -dtb)\n");
|
|
exit(1);
|
|
}
|
|
}
|
|
fixupcontext[FIXUP_ENTRYPOINT] = entry;
|
|
|
|
write_bootloader("bootloader", info->loader_start,
|
|
primary_loader, fixupcontext);
|
|
|
|
if (info->nb_cpus > 1) {
|
|
info->write_secondary_boot(cpu, info);
|
|
}
|
|
}
|
|
info->is_linux = is_linux;
|
|
|
|
for (; cs; cs = CPU_NEXT(cs)) {
|
|
cpu = ARM_CPU(cs);
|
|
cpu->env.boot_info = info;
|
|
qemu_register_reset(do_cpu_reset, cpu);
|
|
}
|
|
}
|